According to most astrophysicists, once you enter a black hole, that’s it for you: gravity will drag you to the singularity — a one-dimensional infinitely small space containing a huge mass — at the speed of light. Then, the black hole will ‘spaghettify you”. Nice.
However, a new study from Berkley University theorises not only that humans could survive going into a black hole, but that their past could be erased, giving way to “infinite futures”.
Physicist Peter Hintz argues that if a human traveller entered a “relatively benign” black hole, they might be able to shed the natural laws of physics — and survive.
How will artificial intelligence, molecular manufacturing, biological engineering and distributed additive manufacturing change the economics of the production of goods and services?
SingularityNET lets anyone create, share, and monetize AI services at scale. The world’s decentralized AI network has arrived. Be part of the revolution and get to know us at this event! You will be able to ask questions to SingularityNET’s CEO Dr. Ben Goertzel.
For the first time ever, SingularityNET will be making a tour in the UK visiting the University of Cambridge, University of Oxford, and Imperial College London. Together with our co-host Eterna Capital, and in collaboration with the Cambridge University Engineering Society, and The Cambridge Guild, we are proud to be visiting the University of Cambridge on the 30th of January to present:
CEO & Dr. Ben Goertzel: How we are building the global AI brain with SingularityNET
The Singularity is near(er)! At least, that’s what the famous inventor and futurist Ray Kurzweil argues. If you’ve ever had an interest in artificial intelligence (AI), robotics, or the future in general, you’ve more than likely heard of Kurzweil. Whether it’s through documentaries, his various written works, or the vast number of interviews he’s been involved in these last few decades, he’s always provided a cautiously optimistic analysis of the world of tomorrow.
His latest interview, which was conducted during last year’s RAAD Festival, was no different.
CERN has revealed plans for a gigantic successor of the giant atom smasher LHC, the biggest machine ever built. Particle physicists will never stop to ask for ever larger big bang machines. But where are the limits for the ordinary society concerning costs and existential risks?
CERN boffins are already conducting a mega experiment at the LHC, a 27km circular particle collider, at the cost of several billion Euros to study conditions of matter as it existed fractions of a second after the big bang and to find the smallest particle possible – but the question is how could they ever know? Now, they pretend to be a little bit upset because they could not find any particles beyond the standard model, which means something they would not expect. To achieve that, particle physicists would like to build an even larger “Future Circular Collider” (FCC) near Geneva, where CERN enjoys extraterritorial status, with a ring of 100km – for about 24 billion Euros.
Experts point out that this research could be as limitless as the universe itself. The UK’s former Chief Scientific Advisor, Prof Sir David King told BBC: “We have to draw a line somewhere otherwise we end up with a collider that is so large that it goes around the equator. And if it doesn’t end there perhaps there will be a request for one that goes to the Moon and back.”
“There is always going to be more deep physics to be conducted with larger and larger colliders. My question is to what extent will the knowledge that we already have be extended to benefit humanity?”
Thanks so much to Luanna Helena for having me on Creatively Speaking Radio to discuss Bioquark Inc. (http://www.bioquark.com) and nature’s clues for human regeneration, disease reversion, and age rejuvenation -
Technologies have often been observed to improve exponentially over time. In practice this often means identifying a constant known as the doubling time. Moore’s law is, classically, the empirical observation that the number of electronic components that can be put on a chip doubles every 18 to 24 months. Today it is frequently stated in terms of the number of computations available per unit of cost, a formulation promoted by Kurzweil. Different doubling times describe the rate of advancement in many technologies.
A frequently noted competitor to Moore’s law is known as Wright’s law, which has aeronautical roots. Wright’s law expresses the idea that performance of a technology—price or a quality metric—improves by a constant percentage for every doubling of the total number produced. Does exploration of outer space conform to behavior like Moore’s law or Wright’s law? Our results are broadly consistent with these laws. (More)